Influence of dimethyl sulfoxide on membrane fluidity under rapid supercooling

Samapika Sahu, Prasanjit Dutta, Ananya Debnath
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Abstract

The effect of dimethyl sulfoxide (DMSO) on a model 1,2-dimyristoyl-sn-glycero-3-phosphocholine lipid membrane is investigated during a rapid supercooling from 350 to 250 K using a total of \(165.0198~\upmu\)s all-atom molecular dynamics simulations. Our findings reveal that the addition of DMSO above a critical concentration induces significant alterations in the gel phase of the membrane at supercooled temperatures, shifting the gel phase to a fluid phase evident from area per lipid, order parameter, and d-spacing. Notably, an anomalous contraction is observed in bilayers in the presence of DMSO with the same critical concentrations as the temperature is cooled from 300 K. As the concentration of DMSO rises at supercooled temperatures, the interface becomes increasingly populated with DMSO molecules, approaching a two-dimensional percolation threshold. This process leads to an expansion in the area occupied by each lipid molecule, creating free space around the lipid tails. Subsequently, the population of DMSO and water at the hydrophobic core becomes energetically favorable at a supercooled temperature compared to the higher temperature above the critical concentration of DMSO. The higher population of DMSO and water at the interface and at the hydrophobic core increases the disorder and fluidity of the lipids and gradually changes the gel phase toward the fluid phase. Thus, our results provide the molecular mechanism of DMSO-induced fluidity of the membrane at supercooled temperature relevant for cell banking in the future.

Abstract Image

二甲基亚砜对快速过冷条件下膜流动性的影响
在从 350 K 到 250 K 的快速过冷过程中,我们使用了总共 165.0198 秒的全原子分子动力学模拟,研究了二甲基亚砜(DMSO)对模型 1,2-二肉豆蔻酰-sn-甘油-3-磷酸胆碱脂膜的影响。我们的研究结果表明,在过冷温度下,超过临界浓度的二甲基亚砜的加入会导致膜的凝胶相发生显著变化,从单位脂质面积、阶次参数和d-间距可以明显看出,凝胶相转变为流体相。值得注意的是,当温度从 300 K 冷却到相同临界浓度的 DMSO 存在时,在双层膜中观察到了异常收缩。这一过程导致每个脂质分子占据的面积扩大,在脂质尾部周围形成自由空间。随后,与 DMSO 临界浓度以上的较高温度相比,疏水核心处的 DMSO 和水的数量在过冷温度下变得能量有利。界面和疏水核心处较多的 DMSO 和水增加了脂质的无序性和流动性,使凝胶相逐渐向流体相转变。因此,我们的研究结果提供了在过冷温度下 DMSO 诱导膜流动性的分子机制,这与未来的细胞银行有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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